Human topoisomerase IIalpha possesses an intrinsic nucleic acid specificity for DNA ligation. Use of 5' covalently activated oligonucleotide substrates to study enzyme mechanism

Despite the importance of topoisomerase II-mediated DNA ligation to the essential physiological functions of the enzyme, the mechanistic details of this important reaction are poorly understood. Because topoisomerase II normally does not release cleaved DNA molecules prior to ligation, it is not known whether all of the nucleic acid specificity of its cleavage/ligation cycle is embodied in DNA cleavage or whether ligation also contributes specificity to the enzyme. All currently available ligation assays require that topoisomerase II cleave the initial DNA substrate before rejoining can be monitored. Consequently, it has been impossible to examine the specificity of DNA ligation separately from that of scission. To address this issue, a cleavage-independent topoisomerase II DNA ligation assay was developed. This assay utilizes a nicked oligonucleotide whose 5'-phosphate terminus at the nick has been activated by covalent attachment to the tyrosine mimic, p-nitrophenol. Human topoisomerase IIalpha and enzymes with active-site mutations that abrogated cleavage activity ligated the activated nick by catalyzing the direct attack of the terminal 3'-OH on the activated 5'-phosphate. Results with different DNA sequences indicate that human topoisomerase IIalpha possesses an intrinsic nucleic acid specificity for ligation that parallels its specificity for DNA cleavage.     

Impact of the C-terminal domain of topoisomerase IIalpha on the DNA cleavage activity of the human enzyme

The enzymatic function of the C-terminal domain of eukaryotic topoisomerase II is not well defined. This region of the enzyme is highly variable and hydrophilic and contains nuclear localization signals and phosphorylation sites. In contrast to eukaryotic topoisomerase II, type II enzymes from chlorella virus completely lack the C-terminal domain. These viral enzymes are characterized by a robust DNA cleavage activity, high coordination between their two active site tyrosyl residues, and reduced sensitivity to anticancer drugs. As a first step toward characterizing the contribution of the C-terminal domain of human topoisomerase IIalpha to enzyme function, the protein was truncated at amino acid 1175, which corresponds to the C-terminal residue of Paramecium bursaria chlorella virus-1 topoisomerase II as determined by BLAST sequence alignment. Although the overall catalytic activity of the resulting enzyme, hTop2alphaDelta1175, was lower than that of full-length topoisomerase IIalpha, the mutant protein displayed a double-stranded DNA cleavage activity that was approximately 2-3-fold higher. While the DNA breaks created by hTop2alphaDelta1175 were primarily double stranded, cuts generated by topoisomerase IIalpha were primarily single stranded. Thus, the enhanced cleavage observed for hTop2alphaDelta1175 appears to be due, at least in part, to an increase in active site coordination. Finally, hTop2alphaDelta1175 displayed a distinctly lower susceptibility to anticancer agents than did topoisomerase IIalpha, despite the fact that it showed a similar binding affinity for etoposide. Therefore, the C-terminal domain of human topoisomerase IIalpha appears to play significant roles in modulating the DNA cleavage/ligation reaction of the enzyme and its response to anticancer agents.     

Positioning the 3'-DNA terminus for topoisomerase II-mediated religation

Despite the importance of the topoisomerase II DNA cleavage/rejoining cycle to genomic integrity, the mechanistic details of religation are poorly understood. Topoisomerase II utilizes covalent protein-DNA interactions to align the 5'-termini of cleaved DNA for religation. However, because the enzyme does not form covalent bonds with the 3'-DNA termini, the basis for the alignment of the 3'-ends is less clear. Three major possibilities exist. The 3'-termini may be positioned for religation (i) by base pairing to their complementary DNA strands, (ii) by base stacking to the adjacent residues, or (iii) by noncovalent interactions with topoisomerase II. To distinguish between these possibilities, the ability of human topoisomerase IIalpha to religate a series of oligonucleotides with altered base pairing or base stacking at their 3'-termini was determined. Substrates containing modifications that disrupted terminal base pairing or base stacking with-out affecting the 3'-terminal base were resealed at wild-type rates. In contrast, substrates that lacked the terminal base (or contained an altered base) displayed very low rates of religation. On the basis of these results, we propose that topoisomerase II positions the 3'-DNA termini for religation through noncovalent protein-DNA contacts.     

Using 3'-bridging phosphorothiolates to isolate the forward DNA cleavage reaction of human topoisomerase IIalpha

The ability to cleave DNA is critical to the cellular and pharmacological functions of human type II topoisomerases. However, the low level of cleavage at equilibrium and the tight coupling of the cleavage and ligation reactions make it difficult to characterize the mechanism by which these enzymes cut DNA. Therefore, to establish a system that isolates topoisomerase II-mediated DNA scission from ligation, oligonucleotide substrates were developed that contained a 3'-bridging phosphorothiolate at the scissile bond. Scission of these substrates generates a 3'-terminal -SH moiety that is a poor nucleophile relative to the normal 3'-terminal -OH group. Consequently, topoisomerase II cannot efficiently ligate phosphorothiolate substrates once they are cleaved. The characteristics of topoisomerase IIalpha-mediated cleavage of phosphorothiolate oligonucleotides were identical to those seen with wild-type substrates, except that no ligation was observed. This unidirectional accumulation of cleavage complexes provided critical information regarding coordination of the protomer subunits of topoisomerase IIalpha and the mechanism of action of topoisomerase II poisons. Results indicate that the two enzyme subunits are partially coordinated and that cleavage at one scissile bond increases the degree of cleavage at the other. Furthermore, anticancer drugs such as etoposide and amsacrine that strongly inhibit topoisomerase II-mediated DNA ligation have little effect on the forward scission reaction. In contrast, abasic sites that increase levels of cleavage complexes without affecting ligation stimulate the forward rate of scission. Phosphorothiolate substrates provide significant advantages over traditional "suicide substrates" and should be valuable for future studies on DNA scission and the topoisomerase II-DNA cleavage complex.     

Vaccinia topoisomerase and Cre recombinase catalyze direct ligation of activated DNA substrates containing a 3'-para-nitrophenyl phosphate ester

DNA topoisomerases and DNA site-specific recombinases are involved in a diverse set of cellular processes but both function by making transient breaks in DNA. Type IB topoisomerases and tyrosine recombinases cleave DNA by transesterification of an active site tyrosine to generate a DNA–3′-phosphotyrosyl–enzyme adduct and a free 5′-hydroxyl (5′-OH). Strand ligation results when the 5′-OH attacks the covalent complex and displaces the enzyme. We describe the synthesis of 3′-phospho-(para-nitrophenyl) oligonucleotides (3′-pNP DNAs), which mimic the natural 3′-phosphotyrosyl intermediate, and demonstrate that such pre-activated strands are substrates for DNA ligation by vaccinia topoisomerase and Cre recombinase. Ligation occurs by direct attack of a 5′-OH strand on the 3′-pNP DNA (i.e., without a covalent protein–DNA intermediate) and generates free para-nitrophenol as a product. The chromogenic DNA substrate allows ligation to be studied in real-time and in the absence of competing cleavage reactions and can be exploited for high-throughput screening of topoisomerase/recombinase inhibitors.     

The strictly conserved Arg-321 residue in the active site of Escherichia coli topoisomerase I plays a critical role in DNA rejoining

The strictly conserved arginine residue proximal to the active site tyrosine of type IA topoisomerases is required for the relaxation of supercoiled DNA and was hypothesized to be required for positioning of the scissile phosphate for DNA cleavage to take place. Mutants of recombinant Yersinia pestis topoisomerase I with hydrophobic substitutions at this position were found in genetic screening to exhibit a dominant lethal phenotype, resulting in drastic loss in Escherichia coli viability when overexpressed. In depth biochemical analysis of E. coli topoisomerase I with the corresponding Arg-321 mutation showed that DNA cleavage can still take place in the absence of this arginine function if Mg(2+) is present to enhance the interaction of the enzyme with the scissile phosphate. However, DNA rejoining is inhibited in the absence of this conserved arginine, resulting in accumulation of the cleaved covalent intermediate and loss of relaxation activity. These new experimental results demonstrate that catalysis of DNA rejoining by type IA topoisomerases has a more stringent requirement than DNA cleavage. In addition to the divalent metal ions, the side chain of this arginine residue is required for the precise positioning of the phosphotyrosine linkage for nucleophilic attack by the 3'-OH end to result in DNA rejoining. Small molecules that can interfere or distort the enzyme-DNA interactions required for DNA rejoining by bacterial type IA topoisomerases could be developed into novel antibacterial drugs.     

The role of lysine 532 in the catalytic mechanism of human topoisomerase I

Based on co-crystal structures of human topoisomerase I with bound DNA, Lys(532) makes a minor groove contact with the strongly preferred thymidine residue at the site of covalent attachment (-1 position). Replacement of Lys(532) with either arginine or alanine has essentially no effect on the sequence preference of the enzyme, indicating that this interaction is not required for the preference for a T at the -1 position. Although both the cleavage and religation activities of the K532R mutant enzyme are reduced, cleavage is reduced to a greater extent than religation. The reverse is true for the K532A mutant enzyme with religation so impaired that the nicked intermediate accumulates during plasmid relaxation assays. Consistent with the shift in the cleavage religation equilibrium toward cleavage for the K532A mutant enzyme, expression of the mutant enzyme in Saccharomyces cerevisiae is cytotoxic, and thus this mutant enzyme mimics the effects of the anticancer drug camptothecin. Cleavage assays with the mutant enzymes using an oligonucleotide containing a 5'-bridging phosphorothiolate indicate that Lys(532) functions as a general acid during cleavage to protonate the leaving 5'-oxygen. It is possible that the contact with the -1 base is important during catalysis to provide positional rigidity to the active site. The corresponding residues in the vaccinia virus topoisomerase and the tyrosine recombinases may have similar critical roles in catalysis.     

Mapping of the active site tyrosine of eukaryotic DNA topoisomerase I

DNA topoisomerase I from the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe was overproduced using the cloned genes. Extracts from cells overproducing DNA topoisomerase I were prepared and incubated with 32P-labeled DNA. Alkali was used to trap the topoisomerase I-DNA covalent intermediate. Most of the DNA was digested with nuclease, and the resultant 32P-labeled topoisomerase I was subjected to cleavage with cyanogen bromide or formic acid. From the molecular weights of the resultant labeled peptides and by comparison of the amino acid sequences derived from the cloned genes, we were able to deduce that the active site tyrosine of eukaryotic DNA topoisomerase I is very near the carboxyl terminus, at amino acid 771 for S. pombe and 727 for S. cerevisiae. Site-directed mutagenesis was used to change tyrosine 727 of S. cerevisiae topoisomerase I to a phenylalanine. The resulting mutant topoisomerase I protein lost all DNA relaxation activity and rendered cells resistant to the topoisomerase I inhibitor, camptothecin. The amino acid sequence of human topoisomerase I has significant similarity to the two yeast topoisomerase I sequences. Based on this similarity, we infer that tyrosine 723 is the active site tyrosine of human enzyme.     

Quinolone action against human topoisomerase IIalpha: stimulation of enzyme-mediated double-stranded DNA cleavage

Several important antineoplastic drugs kill cells by increasing levels of topoisomerase II-mediated DNA breaks. These compounds act by two distinct mechanisms. Agents such as etoposide inhibit the ability of topoisomerase II to ligate enzyme-linked DNA breaks. Conversely, compounds such as quinolones have little effect on ligation and are believed to stimulate the forward rate of topoisomerase II-mediated DNA cleavage. The fact that there are two scissile bonds per double-stranded DNA break implies that there are two sites for drug action in every enzyme-DNA cleavage complex. However, since agents in the latter group are believed to act by locally perturbing DNA structure, it is possible that quinolone interactions at a single scissile bond are sufficient to distort both strands of the double helix and generate an enzyme-mediated double-stranded DNA break. Therefore, an oligonucleotide system was established to further define the actions of topoisomerase II-targeted drugs that stimulate the forward rate of DNA cleavage. Results indicate that the presence of the quinolone CP-115,953 at one scissile bond increased the extent of enzyme-mediated scission at the opposite scissile bond and was sufficient to stimulate the formation of a double-stranded DNA break by human topoisomerase IIalpha. These findings stand in marked contrast to those for etoposide, which must be present at both scissile bonds to stabilize a double-stranded DNA break [Bromberg, K. D., et al. (2003) J. Biol. Chem. 278, 7406-7412]. Moreover, they underscore important mechanistic differences between drugs that enhance DNA cleavage and those that inhibit ligation.     

Recombinogenic flap ligation mediated by human topoisomerase I

Aberration of eukaryotic topoisomerase I catalysis leads to potentially recombinogenic pathways by allowing the joining of heterologous DNA strands. Recently, a new ligation pathway (flap ligation) was presented for vaccinia virus topoisomerase I, in which blunt end cleavage complexes ligate the recessed end of duplex acceptors having a single-stranded 3'-tail. This reaction was suggested to play an important role in the repair of topoisomerase I-induced DNA double-strand breaks. Here, we characterize flap ligation mediated by human topoisomerase I. We demonstrate that cleavage complexes containing the enzyme at a blunt end allow invasion of a 3'-acceptor tail matching the scissile strand of the donor, which facilitates ligation of the recessed 5'-hydroxyl end. However, the reaction was strictly dependent on the length of double-stranded DNA of the donor complexes, and longer stretches of base-pairing inhibited strand invasion. The stabilization of the DNA helix was most probably provided by the covalently bound enzyme itself, since deleting the N-terminal domain of human topoisomerase I stimulated flap ligation. We suggest that stabilization of the DNA duplex upon enzyme binding may play an important role during normal topoisomerase I catalysis by preventing undesired strand transfer reactions. For flap ligation to function in a repair pathway, factors other than topoisomerase I, such as helicases, would be necessary to unwind the DNA duplex and allow strand invasion.     

Base excision repair intermediates as topoisomerase II poisons

Abasic sites are the most commonly formed DNA lesions in the cell and are produced by numerous endogenous and environmental insults. In addition, they are generated by the initial step of base excision repair (BER). When located within a topoisomerase II DNA cleavage site, "intact" abasic sites act as topoisomerase II poisons and dramatically stimulate enzyme-mediated DNA scission. However, most abasic sites in cells are not intact. They exist as processed BER intermediates that contain DNA strand breaks proximal to the damaged residue. When strand breaks are located within a topoisomerase II DNA cleavage site, they create suicide substrates that are not religated readily by the enzyme and can generate permanent double-stranded DNA breaks. Consequently, the effects of processed abasic sites on DNA cleavage by human topoisomerase IIalpha were examined. Unlike substrates with intact abasic sites, model BER intermediates containing 5'- or 3'-nicked abasic sites or deoxyribosephosphate flaps were suicide substrates. Furthermore, abasic sites flanked by 5'- or 3'-nicks were potent topoisomerase II poisons, enhancing DNA scission approximately 10-fold compared with corresponding nicked oligonucleotides that lacked abasic sites. These findings suggest that topoisomerase II is able to convert processed BER intermediates to permanent double-stranded DNA breaks.     

The p53 tumor suppressor stimulates the catalytic activity of human topoisomerase IIalpha by enhancing the rate of ATP hydrolysis

DNA topoisomerase II is an essential nuclear enzyme for proliferation of eukaryotic cells and plays important roles in many aspects of DNA processes. In this report, we have demonstrated that the catalytic activity of topoisomerase IIalpha, as measured by decatenation of kinetoplast DNA and by relaxation of negatively supercoiled DNA, was stimulated approximately 2-3-fold by the tumor suppressor p53 protein. In order to determine the mechanism by which p53 activates the enzyme, the effects of p53 on the topoisomerase IIalpha-mediated DNA cleavage/religation equilibrium were assessed using the prototypical topoisomerase II poison, etoposide. p53 had no effect on the ability of the enzyme to make double-stranded DNA break and religate linear DNA, indicating that the stimulation of the enzyme catalytic activity by p53 was not due to alteration in the formation of covalent cleavable complexes formed between topoisomerase IIalpha and DNA. The effects of p53 on the catalytic inhibition of topoisomerase IIalpha were examined using a specific catalytic inhibitor, ICRF-193, which blocks the ATP hydrolysis step of the enzyme catalytic cycle. Clearly manifested in decatenation and relaxation assays, p53 reduced the catalytic inhibition of topoisomerase IIalpha by ICRF-193. ATP hydrolysis assays revealed that the ATPase activity of topoisomerase IIalpha was specifically enhanced by p53. Immunoprecipitation experiments revealed that p53 physically interacts with topoisomerase IIalpha to form molecular complexes without a double-stranded DNA intermediary in vitro. To investigate whether p53 stimulates the catalytic activity of topoisomerase II in vivo, we expressed wild-type and mutant p53 in Saos-2 osteosarcoma cells lacking functional p53. Wild-type, but not mutant, p53 stimulated topoisomerase II activity in nuclear extract from these transfected cells. Our data propose a new role for p53 to modulate the catalytic activity of topoisomerase IIalpha. Taken together, we suggest that the p53-mediated response of the cell cycle to DNA damage may involve activation of topoisomerase IIalpha.     

Stimulated activity of human topoisomerases IIalpha and IIbeta on RNA-containing substrates.

Eukaryotic topoisomerase II is a dimeric nuclear enzyme essential for DNA metabolism and chromosome dynamics. Central to the activities of the enzyme is its ability to introduce transient double-stranded breaks in the DNA helix, where the two subunits of the enzyme become covalently attached to the generated 5'-ends through phosphotyrosine linkages. Here, we demonstrate that human topoisomerases IIalpha and IIbeta are able to cleave ribonucleotide-containing substrates. With suicide substrates, which are partially double-stranded molecules containing a 5'-recessed strand, cleavage of both strands was stimulated approximately 8-fold when a ribonucleotide rather than a deoxyribonucleotide was present at the scissile phosphodiester of the recessed strand. The existence of a ribonucleotide at the same position in a normal duplex substrate also enhanced topoisomerase II-mediated cleavage, although to a lesser extent. The enzyme covalently linked to the 5'-ribonucleotide in the cleavage complex efficiently performed ligation, and ligation occurred equally well to acceptor molecules terminated by either a 3'-ribo- or deoxyribonucleotide. Besides the enhanced topoisomerase II-mediated cleavage of ribonucleotide-containing substrates, cleavage of such substrates could be further stimulated by ATP or antitumor drugs. In conclusion, the observed in vitro activities of the human topoisomerase II isoforms indicate that the enzymes can operate on RNA or RNA-containing substrates and thus might possess an intrinsic RNA topoisomerase activity, as has previously been demonstrated for Escherichia coli topoisomerase III.     

Chlorella virus Marburg topoisomerase II: high DNA cleavage activity as a characteristic of Chlorella virus type II enzymes

Although the formation of a covalent enzyme-cleaved DNA complex is a prerequisite for the essential functions of topoisomerase II, this reaction intermediate has the potential to destabilize the genome. Consequently, all known eukaryotic type II enzymes maintain this complex at a low steady-state level. Recently, however, a novel topoisomerase II was discovered in Paramecium bursaria chlorella virus-1 (PBCV-1) that has an exceptionally high DNA cleavage activity [Fortune et al. (2001) J. Biol. Chem. 276, 24401-24408]. If robust DNA cleavage is critical to the physiological functions of chlorella virus topoisomerase II, then this remarkable characteristic should be conserved throughout the viral family. Therefore, topoisomerase II from Chlorella virus Marburg-1 (CVM-1), a distant family member, was expressed in yeast, isolated, and characterized. CVM-1 topoisomerase II is 1058 amino acids in length, making it the smallest known type II enzyme. The viral topoisomerase II displayed a high DNA strand passage activity and a DNA cleavage activity that was approximately 50-fold greater than that of human topoisomerase IIalpha. High DNA cleavage appeared to result from a greater rate of scission rather than promiscuous DNA site utilization, inordinately tight DNA binding, or diminished religation rates. Despite the fact that CVM-1 and PBCV-1 topoisomerase II share approximately 67% amino acid sequence identity, the two enzymes displayed clear differences in their DNA cleavage specificity/site utilization. These findings suggest that robust DNA cleavage is intrinsic to the viral enzyme and imply that chlorella virus topoisomerase II plays a physiological role beyond the control of DNA topology.     

DNA cleavage and religation by human topoisomerase II alpha at high temperature.

A common DNA religation assay for topoisomerase II takes advantage of the fact that the enzyme can rejoin cleaved nucleic acids but cannot mediate DNA scission at suboptimal temperatures (either high or low). Although temperature-induced DNA religation assays have provided valuable mechanistic information for several type II enzymes, high-temperature shifts have not been examined for human topoisomerase IIalpha. Therefore, the effects of temperature on the DNA cleavage/religation activity of the enzyme were characterized. Human topoisomerase IIalpha undergoes two distinct transitions at high temperatures. The first transition occurs between 45 and 55 degrees C and is accompanied by a 6-fold increase in the level of DNA cleavage at 60 degrees C. It also leads to a loss of DNA strand passage activity, due primarily to an inability of ATP to convert the enzyme to a protein clamp. The enzyme alterations that accompany the first transition appear to be stable and do not revert at lower temperature. The second transition in human topoisomerase IIalpha occurs between 65 and 70 degrees C and correlates with a precipitous drop in the level of DNA scission. At 75 degrees C, cleavage falls well below amounts seen at 37 degrees C. This loss of DNA scission appears to result from a decrease in the forward rate of DNA cleavage rather than an increase in the religation rate. Finally, similar high-temperature alterations were observed for yeast topoisomerase II and human topoisomerase IIbeta, suggesting that parallel heat-induced transitions may be widespread among type II topoisomerases.     

Major groove interactions of vaccinia Topo I provide specificity by optimally positioning the covalent phosphotyrosine linkage

Vaccinia DNA topoisomerase (vTopo) is a prototypic eukaryotic type I topoisomerase that shows high specificity for nucleophilic substitution at a single phosphodiester linkage in the pentapyrimidine recognition sequence 5'-(C/T)+5 C+4 C+3 T+2 T+1 p / N(-1). This reaction involves reversible transesterification where the active site tyrosine of the enzyme and a 5'-hydroxyl nucleophile of DNA compete for attack at the phosphoryl group. The finite lifetime of the covalent phosphotyrosine adduct allows the enzyme to relax multiple supercoils by rotation of the 5'-OH strand before the DNA backbone is religated. To dissect the nature of the unique sequence specificity, subtle modifications to the major groove of the GGGAA 5'-sequence of the nonscissile strand were introduced and their effects on each step of the catalytic cycle were measured. Although these modifications had no effect on noncovalent DNA binding (K(D)) or the rate of reversible DNA cleavage (k(cl)), significant decreases in the cleavage equilibrium (K(cl) = k(cl)/k(r)) arising from increased rates of 5'-hydroxyl attack (k(r)) at the phosphotyrosine linkage were observed. These data and other findings support a model in which major groove interactions are used to position the phosphotyrosine linkage relative to the mobile 5'-hydroxyl nucleophile. In the absence of native sequence interactions, the phosphotyrosine has a higher probability of encountering the 5'-hydroxyl nucleophile, leading to an enhanced rate of ligation and a diminished equilibrium constant for cleavage. By this unusual specificity mechanism, the enzyme prevents formation of stable covalent adducts at nonconsensus sites in genomic DNA.     

N-acetyl-p-benzoquinone imine, the toxic metabolite of acetaminophen, is a topoisomerase II poison

Although acetaminophen is the most widely used analgesic in the world, it is also a leading cause of toxic drug overdoses. Beyond normal therapeutic doses, the drug is hepatotoxic and genotoxic. All of the harmful effects of acetaminophen have been attributed to the production of its toxic metabolite, N-acetyl-p-benzoquinone imine (NAPQI). Since many of the cytotoxic/genotoxic events triggered by NAPQI are consistent with the actions of topoisomerase II-targeted drugs, the effects of this metabolite on human topoisomerase IIalpha were examined. NAPQI was a strong topoisomerase II poison and increased levels of enzyme-mediated DNA cleavage >5-fold at 100 microM. The compound induced scission at a number of DNA sites that were similar to those observed in the presence of the topoisomerase II-targeted anticancer drug etoposide; however, the relative site utilization differed. NAPQI strongly impaired the ability of topoisomerase IIalpha to reseal cleaved DNA molecules, suggesting that inhibition of DNA religation is the primary mechanism underlying cleavage enhancement. In addition to its effects in purified systems, NAPQI appeared to increase levels of DNA scission mediated by human topoisomerase IIalpha in cultured CEM leukemia cells. In contrast, acetaminophen did not significantly affect the DNA cleavage activity of the human enzyme in vitro or in cultured CEM cells. Furthermore, the analgesic did not interfere with the actions of etoposide against the type II enzyme. These results suggest that at least some of the cytotoxic/genotoxic effects caused by acetaminophen overdose may be mediated by the actions of NAPQI as a topoisomerase II poison.     

Exocyclic DNA lesions stimulate DNA cleavage mediated by human topoisomerase II alpha in vitro and in cultured cells

DNA adducts are mutagenic and clastogenic. Because of their harmful nature, lesions are recognized by many proteins involved in DNA repair. However, mounting evidence suggests that lesions also are recognized by proteins with no obvious role in repair processes. One such protein is topoisomerase II, an essential enzyme that removes knots and tangles from the DNA. Because topoisomerase II generates a protein-linked double-stranded DNA break during its catalytic cycle, it has the potential to fragment the genome. Previous studies indicate that abasic sites and other lesions that distort the double helix stimulate topoisomerase II-mediated DNA cleavage. Therefore, to further explore interactions between DNA lesions and the enzyme, the effects of exocyclic adducts on DNA cleavage mediated by human topoisomerase IIalpha were determined. When located within the four-base overhang of a topoisomerase II cleavage site (at the +2 or +3 position 3' relative to the scissile bond), 3,N(4)-ethenodeoxycytidine, 3,N(4)-etheno-2'-ribocytidine, 1,N(2)-ethenodeoxyguanosine, pyrimido[1,2-a]purin-10(3H)-one deoxyribose (M(1)dG), and 1,N(2)-propanodeoxyguanosine increased DNA scission approximately 5-17-fold. Enhanced cleavage did not result from an increased affinity of topoisomerase IIalpha for adducted DNA or a decreased rate of religation. Therefore, it is concluded that these exocyclic lesions act by accelerating the forward rate of enzyme-mediated DNA scission. Finally, treatment of cultured human cells with 2-chloroacetaldehyde, a reactive metabolite of vinyl chloride that generates etheno adducts, increased cellular levels of DNA cleavage by topoisomerase IIalpha. This finding suggests that type II topoisomerases interact with exocyclic DNA lesions in physiological systems.     

Cobalt enhances DNA cleavage mediated by human topoisomerase II alpha in vitro and in cultured cells

Although cobalt is an essential trace element for humans, the metal is genotoxic and mutagenic at higher concentrations. Treatment of cells with cobalt generates DNA strand breaks and covalent protein-DNA complexes. However, the basis for these effects is not well understood. Since the toxic events induced by cobalt resemble those of topoisomerase II poisons, the effect of the metal on human topoisomerase IIalpha was examined. The level of enzyme-mediated DNA scission increased 6-13-fold when cobalt(II) replaced magnesium(II) in cleavage reactions. Cobalt(II) stimulated cleavage at all DNA sites observed in the presence of magnesium(II), and the enzyme cut DNA at several "cobalt-specific" sites. The increased level of DNA cleavage in the presence of cobalt(II) was partially due to a decrease in the rate of enzyme-mediated religation. Topoisomerase IIalpha retained many of its catalytic properties in reactions that included cobalt(II), including sensitivity to the anticancer drug etoposide and the ability to relax and decatenate DNA. Finally, cobalt(II) stimulated topoisomerase IIalpha-mediated DNA cleavage in the presence of magnesium(II) in purified systems and in human MCF-7 cells. These findings demonstrate that cobalt(II) is a topoisomerase II poison in vitro and in cultured cells and suggest that at least some of the genotoxic effects of the metal are mediated through topoisomerase IIalpha.